FR2936841A1 - THERMAL EXCHANGER STRUCTURE AND ISOTHERMAL COMPRESSION OR RELIEF CHAMBER. - Google Patents

Abstract

The invention relates to a thermodynamic machine comprising at least one chamber (21) in which it is desired to perform an expansion and / or isothermal compression, this chamber being delimited longitudinally by first and second movable walls relative to each other (23, 25). The chamber (21) is divided by partitions (31, 33) extending longitudinally from each of the first and second walls, the partitions being nested one inside the other, the distance between partitions extending from the same wall being such that the ratio between this distance squared and the cycle time of the thermodynamic machine is less than the average thermal diffusivity of the gas contained in the chamber.

Description

B9065 1 THERMAL EXCHANGER STRUCTURE AND ISOTHERMAL COMPRESSION OR RELIEF CHAMBER

Field of the Invention The present invention generally relates to a heat exchanger structure. The present invention also relates to a chamber in which isothermal compression and / or expansion is performed. The present invention further relates to a high efficiency reversible thermodynamic machine comprising such a chamber, for example a Stirling machine. DESCRIPTION OF THE PRIOR ART Stirling machines are sometimes used for the production of industrial refrigeration and in some military or space applications. These machines have the advantage of being used as an engine or to produce heat or cold, without using refrigerants that are generally pollutants. Another advantage of a Stirling machine is that its hot source is external and therefore this source can be obtained using any known fuel or even solar radiation. In a Stirling cycle, a gas, for example air, hydrogen or helium, is subjected to a cycle comprising four phases: isochoric heating, detent B9065

2 isothermal, isochoric cooling and isothermal compression. Figure 1 is a generic diagram of a Stirling machine. A first chamber 3 is connected to a second chamber 5 via a first heat exchanger 7, a regenerator 9 and a second heat exchanger 11. The assembly comprising the chambers, the exchangers and the regenerator can have a cylindrical shape. The first and second exchangers 7 and 11 are, respectively, in contact with a hot source at a hot temperature TC and with a cold source at a cold temperature TF. The chambers 3 and 5 are closed, respectively, by movable pistons 13 and 15 which delimit the variable volumes of the chambers 3 and 5. It will be understood that the various elements of the Stirling machine shown in FIG. 1 can be movable relative to each other. to others in different ways: for example, the two pistons 13 and 15 may be movable and the regenerator 9 and the exchangers 7 and 11 to be fixed, in the case of a so-called alpha configuration. One of the pistons 13 or 15 can also be fixed if the central part of the machine is movable. It is also possible that the assembly consisting of the regenerator 9 and exchangers 7 and 11 is fixed and the variable volumes of the chambers 3 and 5 consist of a single variable volume separated into two parts by a movable wall, said displacer. This configuration is called a beta or gamma configuration. Figures 2A to 2D illustrate steps of a Stirling engine cycle. At an arbitrary initial state A illustrated in FIG. 2A, a volume of gas is stored in the first chamber 3, the second chamber 5 preferably having a zero or low volume. The gas in the first chamber 3 is heated by the hot source and its pressure increases. This causes the piston 13 to move to arrive at a state B in which the volume occupied by the gas in the chamber 3 is greater than the volume of B9065

This same chamber is in state A. During the isothermal expansion stage (step A to B), mechanical work is recovered. Isochoric cooling then makes it possible to go from state B to state C in which the gas in hot chamber 3 is transferred to cold chamber 5. During this transfer, the gas stored in chamber 3 passes through regenerator 9 and reaches room 5 while cooling. The heat contained in the hot gas is "recovered" in the regenerator, as we shall see later, and the gas cools.

An isothermal compression makes it possible to go from the state C to a state D in which the volume occupied by the gas in the chamber 5 is smaller than the volume of this same chamber in the state C. This compression is achieved by actuating the piston 15 in order to reduce the volume of the chamber 5. This step consumes energy, but less than the energy supplied between the states A and B. Finally, an isochoric transfer makes it possible to go from the state D to the initial state In which the gas is stored in the hot chamber 3. During this step, the gas passes from the cold chamber 5 to the hot chamber 3 via the regenerator 9. In the regenerator, the heat recovered during the isochoric cooling ( step B to c) is returned to the gas during its second pass through the regenerator (step D to A). Thus, the gas heats up before coming into contact with the exchanger 7. It will be noted that, in the known machines, the chambers 3 and 5 are almost completely empty during the cycle. In motor cycle, the mechanical work recovered during the expansion between steps A and B is used in part for the isothermal compression (steps C to D). The regenerator allows the heat recovered during the transition from state B to state C to be distributed to the gas during the transition from state D to state A and to avoid heat losses. In fact, the regenerator operates as a countercurrent heat exchanger: when a hot gas passes into a cold regenerator, it cools by heating B9065

4 the regenerator and, conversely, a cold gas passing through the hot regenerator heats up by cooling the regenerator. To ensure its function, it is important that the regenerator is made of materials that conduct little heat in the direction of the gas flow, for example insulating materials. Here machines are considered that are reversible, that is to say that can be used in motor cycle or heat pump cycle. It should be noted that this definition of reversibility differs from the current definition in which a reversible machine is a machine whose cold and hot sources can be reversed. A problem with current Stirling machines is that, if they have a good performance for an engine cycle, they will have a low efficiency in the heat pump cycle, and vice versa.

The low yields when using these machines in a reversible manner or over a wide operating range come from the various losses that occur therein and, in particular, temperature differences in heat exchange. Another source of irreversible losses in Stirling machines, and in any machine implementing theoretically isothermal compressions or detents, is that the real systems are far from being able to allow such isothermal compressions and relaxations. Summary An object of an embodiment of the present invention is to provide a thermodynamic machine whose cycle involves compressions and / or relaxations whose isothermal nature is close to ideal. An object of an embodiment of the present invention is to provide a thermodynamic machine with low losses and high efficiency over a wide operating range. An object of an embodiment of the present invention is to provide a reversible thermodynamic machine.

B9065

An object of an embodiment of the present invention is to provide an optimized heat exchanger. Thus, an embodiment of the present invention provides a thermodynamic machine comprising at least one chamber in which it is desired to carry out an expansion and / or isothermal compression, this chamber being delimited longitudinally by first and second movable walls, one by relationship to the other, characterized in that said chamber is divided by partitions extending longitudinally from each of the first and second walls, the partitions being nested one inside the other, the distance between partitions extending from of the same wall being such that the ratio between this distance squared and the cycle time of the thermodynamic machine is less than the average thermal diffusivity of the gas contained in the chamber. According to one embodiment of the present invention, the distance between partitions extending from the same wall is such that said ratio is less than half the average thermal diffusivity of the gas contained in the chamber.

According to one embodiment of the present invention, at least one wall of the chamber is intended to be brought into contact with a heat source. According to one embodiment of the present invention, the chamber is cylindrical and the partitions have, in section in a direction perpendicular to the length of the chamber, a spiral shape. According to one embodiment of the present invention, the turns of the partitions are separated by a corrugated strip. According to one embodiment of the present invention, the turns of the partitions are separated by two crenellated strips placed in opposition and whose crenellations overlap. According to one embodiment of the present invention, the chamber is cylindrical and the partitions form, in section in a direction perpendicular to the length of the chamber, a set of corrugated portions parallel to each other.

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According to one embodiment of the present invention, the chamber is cylindrical and the partitions form, in section in a direction perpendicular to the length of the chamber, a set of plane portions parallel to each other.

According to one embodiment of the present invention, at least one wall forms the end of a controllable piston. According to one embodiment of the present invention, the partitions are made of a thermally conductive ceramic, for example silicon carbide or aluminum nitride, made of copper, aluminum or steel. BRIEF DESCRIPTION OF THE DRAWINGS These and other objects, features, and advantages will be set forth in detail in the following description of particular embodiments in a non-limiting manner with reference to the accompanying drawings, in which: FIG. , is a generic diagram of a Stirling machine; FIGS. 2A to 2D, previously described, illustrate steps of a cycle of a Stirling engine; Figs. 3A-3C are sectional views of a portion of a machine according to one embodiment of the present invention, in several configurations; Figures 4 and 5 are two perspective views of machine portions according to one embodiment of the present invention; FIG. 6 illustrates a possible embodiment of a half-exchanger according to an embodiment of the present invention; Fig. 7 is a sectional view of a Stirling machine according to one embodiment of the present invention; Figures 8A and 8B illustrate another possible embodiment of a half-exchanger according to an embodiment of the present invention; and B9065

Fig. 9 is a graph showing an advantage of a machine according to an embodiment of the present invention. For the sake of clarity, the same elements have been designated by the same references in the various figures and, in addition, the various figures are not drawn to scale. DETAILED DESCRIPTION One embodiment of the present invention provides, firstly, to place heat exchangers directly in compression and expansion chambers. In addition, it is intended to form compression and expansion chambers in which the exchangers comprise numerous portions forming partitions in the chambers. These partitions extend from two walls facing the chambers and intersect when the volume of the chamber decreases. Figures 3A to 3C illustrate, in longitudinal sectional view, a compression or expansion chamber as described above constituting, for example, a part of a Stirling machine. These figures illustrate different states during isothermal expansion. In Figure 3A, a chamber 21 is formed in a cylinder and is delimited by two walls 23 and 25 movable relative to each other in the cylinder. In the example shown, consider a movable wall 23 associated with a piston pin 27, and a fixed wall 25 fixed for example to a regenerator 29 (not shown in detail). It will be understood that the walls 23 and 25 may be movable relative to each other in another way. The wall 23 is sealed and the wall 25 is gas permeable, for example provided with numerous perforations. Partitions 31 extend into the chamber 21 from the wall 23 and the partitions 33 extend into the chamber 21 from the wall 25. The partitions 31 and 33 extend in the longitudinal direction of the cylinder and are arranged, in view B9065

8 in section, alternately. The partitions 31 and 33 form two half-exchangers. In the state of FIG. 3A, the ends of the partitions 31 are close to the wall 25 and the ends of the partitions 33 are close to the wall 23. The volume of the chamber 21 is therefore minimal. A hot source (or cold in the case of a reverse compression) is connected to one of the walls 23 or 25, here the wall 23, by suitable means not shown. The wall 23 may be in direct contact with the heat source or be in contact therewith via the flow of a hot or cold fluid. FIG. 3C illustrates the device when the volume of the chamber 21 is maximum, that is to say that the piston 23-27 and the partitions 31 are remote from the wall 25 at the maximum. In the figure, the free ends of the partitions 31 and 33 are shown facing each other in the chamber 21. It may also be provided that the ends of the partitions 31 and 33 are slightly spaced apart from each other. Figure 3B illustrates the device in an intermediate position between the positions of Figures 3A and 3C. The nested structure of the two half-exchangers allows that, at any moment, each molecule of the gas present in the chamber 21 is relatively close to a partition 31 or 33. Thus, in the case of an expansion where the partitions 31 and 33 are hot, all gas molecules are close to a hot partition during expansion, which prevents the formation of gas pockets having a lower temperature than the heat source and provides isothermal expansion. The structure presented here thus makes it possible to improve the ability of the assembly to conduct the heat of the heat source towards the gas of the chamber 21 and to mitigate the losses related to the temperature differences between the heat source and the gas . To ensure good exchanges between the heat source and the gas and avoid losses by dead volume in the B9065

9, the inventor provides that the partitions are arranged such that: d2 / T <D, d being the distance between two successive partitions 31 or 33 5 of the same half-exchanger; T being the cycle time of the thermodynamic machine (i.e., the round trip time in the case of the Stirling machine described in connection with FIGS. 2A-2D); and D being the average thermal diffusivity on a gas cycle in the chamber. Preferably, the ratio d2 / T will be less than half the thermal diffusivity D of the gas. This makes it possible to maintain a substantially uniform gas temperature in the chamber 21, substantially equal to the temperature of the heat source, and thus to perform compressions and relaxations whose isothermal nature is close to ideal. The partitions 31 and 33 may be of a thermally conductive material, for example a ceramic such as silicon carbide, aluminum nitride, or be of copper or aluminum. In this case, it is understood that in the position of Figure 3A, the partitions 33 are heated by the partitions 31 through the gas. During the expansion, the partitions 33 distribute the heat stored in the gas, and in particular the gas located near the wall 25. To ensure proper operation, it will be understood that the cycle time of the machine must be long enough for the heat exchange between the partitions 31 and 33 and the gas have time to be done. The inventor has noted that the partitions 33 may also be formed of low-conductive materials, without altering the isothermal nature of the detentions / compressions. Similarly, the partitions 31 may be formed of low-conductive materials, except at their ends connected to the wall 23. In this case, in the state of FIG. 3A, the heat is transmitted from the wall 23. to zones B9065

10 of the partitions 31 and then, via the gas, at the free ends of the partitions 33. During the expansion, the free ends of the partitions 33 are successively opposite the different parts of the partitions 31 and the The heat thus passes from the end of the partitions 33 to all the partitions 31, and then again from the partitions 31 to the partitions 33. When the volume of the chamber 21 decreases, the heat also passes between the partitions 31 and the partitions 33 through the gas. Thus, during a cycle, the partitions 31 and 33 are entirely hot and transmit their heat to the gas. In the case where a low-conductive material is used for the partitions 31 and 33, the following relation must be satisfied: Xgaz .a 2 of the partition Xgaz being the thermal conductivity of the gas; Xcloison being the thermal conductivity of the material constituting the partitions 31 and 33; a being the amplitude of the relative movement of the partitions 31 and 33; 20 being the distance separating two successive partitions 31 and 33 belonging to two different half-exchangers; and e being the average thickness of the partitions 31 and 33. The possible use of low-conductive materials enables partitions 31 and 33 to be formed of many materials, for example lightweight materials, low cost materials, or other materials well suited to the formation of such exchangers, for example steel. It will be noted that the presented structure comprising two reciprocating half-reciprocating heat exchangers can be generalized to form any type of exchanger between a hot (or cold) source and a gas. Indeed, it is advantageous to take advantage of the improved propagation of heat between the half-exchangers, because of their relative movements and their interweaving, to form any type of exchanger, by B9065

11 example radiators in which a gas circulates. For example, the gas could enter one of the walls and exit through the opposite wall. As an example of numerical values, the distance d between the partitions 31 and 33 may be between 0.3 and 2 mm and the partitions may have a thickness of between 0.1 and 0.6 mm, if the gas in the chamber 21 is hydrogen or helium. The cylinder of the machine may have a diameter of between 15 and 20 cm and the wall 23 may move about 3 cm in the cylinder. With such dimensions, a cycle time of between 0.02 and 0.5 seconds makes it possible to satisfy the inequality d2 / T <D. It will also be noted that the losses in the exchangers are further reduced if the partitions 31, 33 are slightly thinner at their free ends than at their holding ends (towards the walls 23 and 25). Figure 4 is a perspective view of portions of a machine capable of performing isothermal compression or expansion according to one embodiment of the present invention. In this figure, the outer cylinder in which the elements of the machine move is not shown for the sake of simplicity. In addition, the partitions 31 and 33 have been shown remote from each other for ease of understanding. In practice, these partitions are nested within each other. In this embodiment, the partitions 31 and 33 have, in sectional view in a plane perpendicular to the length of the chamber, spiral shapes. A first spiral forms the partitions 31 and a second spiral forms the partitions 33. The spirals 31 and 33 are provided to interlock one into the other during the decrease in the volume of the chamber 21. FIG. perspective view of portions of a machine capable of performing isothermal compression or expansion according to another embodiment of the present invention.

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In this embodiment, the partitions 31 and 33 consist, in sectional view along a direction perpendicular to the length of the chamber, of numerous plates parallel to each other and separated by a step. In the example shown, the plates are corrugated to improve their hold, but note that these plates can also be flat. The corrugated portions 31 are offset from the corrugated portions 33, for example by half a step, so that these portions interlock without touching during the variation of the volume of the chamber 21.

The wall 23, which is a wall external to the system, must be impervious to the passage of the gas. Thus, in the wall 23, the portions 31, whether spiral or in the form of parallel plates, are separated by a material for sealing the gas and / or are attached to a piston body. Conversely, the internal walls of the system, for example the wall 25 of FIGS. 3A to 3C, have two roles: to allow the portions 33 to be held and to allow the gas to pass towards, for example, a regenerator. Thus, they may for example be perforated.

FIG. 6 illustrates a possible embodiment of a structure for holding a spiral-shaped partition. To maintain a spiral-shaped partition 31 or 33 such as that of FIG. 4, spacing and mechanical resistance means may be placed between the different turns on the side where the spiral is attached to a wall. In the example of FIG. 6, such a means consists of a strip 41 which is rolled together with the strip of thermally conductive or insulating material and which is therefore found inside the winding. In this example, the band 41 is corrugated and the height of the undulations fixes the pitch between the turns of the spiral 31, 33. It will be noted that the structure of FIG. 6 can also be used to form the walls 25, the band 41 serving maintaining the wall 25 while allowing the gas to flow towards the regenerator. In the case where the band 41 is located between conductive turns, this B9065

The strip will preferably be of high conductivity, for example an aluminum alloy. Figure 7 is a detailed sectional view of the body of a Stirling machine embodying an embodiment of the present invention. The machine is formed in a cylinder 51 and comprises a first chamber 53 and a second chamber 55 separated by a regenerator 57. An exchanger consisting of two half-exchangers as shown above is formed in each of the chambers 53 and 55. A first half-exchanger 59, respectively 61, located in the chamber 53, respectively 55, extends from a machine external wall 63, respectively 65. A second half-exchanger 67, respectively 69 located in the chamber 53, respectively 55, extends from a machine-internal wall 71, 73, respectively, which delimits the location of the regenerator. In the example shown, the regenerator 51 consists of partitions 75, 77 which extend, respectively, from the walls 71 and 73. The partitions 75 and 77 are shown nested, for example in a form identical to that of the portions 59 and 67 or 61 and 69. The partitions 75 and 77 are preferably made of a poor thermal conductor material but having good thermal exchange properties with the gas, that is to say a sufficient thermal effusivity. For example, partitions 75 and 77 may be polycarbonate. Guides parallel to the gas flow can be added to the regenerator to ensure that the gas passing through it runs the same path in both directions of travel. It should be noted that the structure of the regenerator described here is only one example and that any type of known regenerator can be used with exchangers such as that of FIGS. 3A to 3C. In the example shown, a central shaft 79 is located in the center of the cylinder 51. This shaft contains elements that allow the positioning of the different elements of the thermodynamic machine relative to each other. The B9065

14 partitions 59, 67, 61 and 69, or even the partitions 75 and 77, may be formed in the form of a spiral around the shaft 79. Elements allowing sealing, thermal insulation, mechanical retention and / or the displacement of the different walls 63, 65, 71 and 73 in the cylinder 51 are represented in FIG. 7 by hatched portions. FIGS. 8A and 8B illustrate another possible embodiment of a structure for holding a spiral-shaped partition.

In FIG. 8A, a layer 31, 33, thermally conductive or not, is wound around an axis 81. During the winding of the layer 31, 33 on the axis 81, two layers of the layer are also wound 31, 33, two strips 83 and 85 whose shape in plan view is castellated. The two strips 83 and 85 are positioned one on the other so that the slots are in opposition and slightly superimposed on each other. It will be noted that the arrangement of the strips 83 and 85 on the material 31, 33 is represented in FIG. 8A only at the end of the winding.

FIG. 8B illustrates better the arrangement of the strips 83 and 85 with respect to one another and the superposition of portions of the slots of these strips. The superposition of the strips 83 and 85 forms a retention of the material winding 31-33 while allowing the passage of gas between the different turns of the structure of FIG. 8A. Thus, the structure of FIGS. 8A and 8B can have the same function as that of FIG. 6. FIG. 9 is a curve illustrating the corrective effect (Eff) associated with the use of a device according to a implementation compared to the use of a conventional device (non-partitioned chamber), in percentage, during expansion or compression, as a function of the ratio DT / d2. Since the ratio d2 / T must be smaller than the diffusion D of the gas, this means that the ratio D.T / d2 must be greater than 1. In this curve, a corrective effect of 0% B9065

15 means that the losses due to the temperature differences in the chamber during the compressions and relaxations are not attenuated, and a corrective effect of 100% means that these losses are non-existent.

The use of the structures described here provides a corrective effect of about 50% when the ratio DT / d2 is of the order of 2 and about 90% when this ratio is of the order of 10. Thus, the The invention makes it possible to greatly reduce the losses associated with the temperature differences during the compressions and relaxations and thus to carry out isothermal transformations. The use of nested exchangers makes it possible to obtain Stirling machines capable of having a yield of 85% of the maximum yield of Carnot over important operating ranges. It is also possible to form machines with a lower volume for a yield similar to that of current machines. In addition, the efficiency is stable over a wide range of hot and cold temperatures, without changing the geometry of the machine. The efficiency also remains good over large power ranges, by varying the cycle time. Good performance is also obtained in case of reversible operation. Particular embodiments of the present invention have been described. Various variations and modifications will be apparent to those skilled in the art. In particular, it will be appreciated that the various advantages of the invention with respect to the application of this invention to reversible Stirling machines have been described herein. It will be noted that the formation of conductive partitions in compression or expansion chambers to ensure the isothermal nature of these compressions or relaxations can be applied to any machine performing such transformations, for example Ericsson machines. The invention can also be applied to any type of compressor or linear piston compressed air machine.

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It will also be noted that the invention applies to cylindrical compression and / or expansion chambers of any shape, of revolution or not.

Claims (10)

REVENDICATIONS1. Thermodynamic machine comprising at least one chamber (21) in which it is desired to carry out an expansion and / or isothermal compression, this chamber being delimited longitudinally by first and second walls movable relative to each other (23, 25) , characterized in that said chamber is divided by partitions (31, 33) extending longitudinally from each of the first and second walls, the partitions being nested one inside the other, the distance between partitions extending from of the same wall being such that the ratio between this distance (d) squared and the cycle time (T) of the thermodynamic machine is lower than the average thermal diffusivity (D) of the gas contained in the chamber (d2 / T <D). 2. Machine according to claim 1, wherein the distance between partitions extending from the same wall is such that said ratio is less than half the average thermal diffusivity (D) of the gas contained in the chamber (21). ). 3. Machine according to claim 1 or 2, wherein at least one wall (23, 25) of the chamber is intended to be brought into contact with a heat source. 4. Machine according to any one of claims 1 to 3, wherein the chamber is cylindrical and wherein the partitions (31, 33) have, in section in a direction perpendicular to the length of the chamber, a spiral shape. 5. Machine according to claim 4, wherein the turns of the partitions (31, 33) are separated by a corrugated strip (41). 6. Machine according to claim 4, wherein the turns of the partitions (31, 33) are separated by two crenellated strips (83, 85) placed in opposition and whose slots overlap. 7. Machine according to any one of claims 1 to 3, wherein the chamber is cylindrical and in which the partitions (31, 33) form, in section along a direction perpendicular to the length of the chamber, a set of portions. waved parallel to each other. 8. Machine according to any one of claims 1 to 3, wherein the chamber is cylindrical and wherein the partitions (31, 33) form, in section in a direction perpendicular to the length of the chamber, a set of planar portions. parallel to each other. 9. Machine according to any one of claims 1 to 8, wherein at least one wall (23, 25) forms the end 10 of a controllable piston. 10. Machine according to any one of claims 1 to 9, wherein the partitions (31, 33) are made of a thermally conductive ceramic, for example silicon carbide or aluminum nitride, copper, aluminum or aluminum. steel.